//===-- ProfileGenerator.h - Profile Generator -----------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #ifndef LLVM_TOOLS_LLVM_PROGEN_PROFILEGENERATOR_H #define LLVM_TOOLS_LLVM_PROGEN_PROFILEGENERATOR_H #include "CSPreInliner.h" #include "ErrorHandling.h" #include "PerfReader.h" #include "ProfiledBinary.h" #include "llvm/ProfileData/SampleProfWriter.h" #include #include using namespace llvm; using namespace sampleprof; namespace llvm { namespace sampleprof { class ProfileGenerator { public: ProfileGenerator(){}; virtual ~ProfileGenerator() = default; static std::unique_ptr create(const BinarySampleCounterMap &BinarySampleCounters, enum PerfScriptType SampleType); virtual void generateProfile() = 0; // Use SampleProfileWriter to serialize profile map virtual void write(std::unique_ptr Writer, StringMap &ProfileMap); void write(); protected: /* For each region boundary point, mark if it is begin or end (or both) of the region. Boundary points are inclusive. Log the sample count as well so we can use it when we compute the sample count of each disjoint region later. Note that there might be multiple ranges with different sample count that share same begin/end point. We need to accumulate the sample count for the boundary point for such case, because for the example below, |<--100-->| |<------200------>| A B C sample count for disjoint region [A,B] would be 300. */ void findDisjointRanges(RangeSample &DisjointRanges, const RangeSample &Ranges); // Used by SampleProfileWriter StringMap ProfileMap; }; class CSProfileGenerator : public ProfileGenerator { protected: const BinarySampleCounterMap &BinarySampleCounters; public: CSProfileGenerator(const BinarySampleCounterMap &Counters) : BinarySampleCounters(Counters){}; public: void generateProfile() override; // Remove adjacent repeated context sequences up to a given sequence length, // -1 means no size limit. Note that repeated sequences are identified based // on the exact call site, this is finer granularity than function recursion. template static void compressRecursionContext(SmallVectorImpl &Context, int32_t CSize = MaxCompressionSize) { uint32_t I = 1; uint32_t HS = static_cast(Context.size() / 2); uint32_t MaxDedupSize = CSize == -1 ? HS : std::min(static_cast(CSize), HS); auto BeginIter = Context.begin(); // Use an in-place algorithm to save memory copy // End indicates the end location of current iteration's data uint32_t End = 0; // Deduplicate from length 1 to the max possible size of a repeated // sequence. while (I <= MaxDedupSize) { // This is a linear algorithm that deduplicates adjacent repeated // sequences of size I. The deduplication detection runs on a sliding // window whose size is 2*I and it keeps sliding the window to deduplicate // the data inside. Once duplication is detected, deduplicate it by // skipping the right half part of the window, otherwise just copy back // the new one by appending them at the back of End pointer(for the next // iteration). // // For example: // Input: [a1, a2, b1, b2] // (Added index to distinguish the same char, the origin is [a, a, b, // b], the size of the dedup window is 2(I = 1) at the beginning) // // 1) The initial status is a dummy window[null, a1], then just copy the // right half of the window(End = 0), then slide the window. // Result: [a1], a2, b1, b2 (End points to the element right before ], // after ] is the data of the previous iteration) // // 2) Next window is [a1, a2]. Since a1 == a2, then skip the right half of // the window i.e the duplication happen. Only slide the window. // Result: [a1], a2, b1, b2 // // 3) Next window is [a2, b1], copy the right half of the window(b1 is // new) to the End and slide the window. // Result: [a1, b1], b1, b2 // // 4) Next window is [b1, b2], same to 2), skip b2. // Result: [a1, b1], b1, b2 // After resize, it will be [a, b] // Use pointers like below to do comparison inside the window // [a b c a b c] // | | | | | // LeftBoundary Left Right Left+I Right+I // A duplication found if Left < LeftBoundry. int32_t Right = I - 1; End = I; int32_t LeftBoundary = 0; while (Right + I < Context.size()) { // To avoids scanning a part of a sequence repeatedly, it finds out // the common suffix of two hald in the window. The common suffix will // serve as the common prefix of next possible pair of duplicate // sequences. The non-common part will be ignored and never scanned // again. // For example. // Input: [a, b1], c1, b2, c2 // I = 2 // // 1) For the window [a, b1, c1, b2], non-common-suffix for the right // part is 'c1', copy it and only slide the window 1 step. // Result: [a, b1, c1], b2, c2 // // 2) Next window is [b1, c1, b2, c2], so duplication happen. // Result after resize: [a, b, c] int32_t Left = Right; while (Left >= LeftBoundary && Context[Left] == Context[Left + I]) { // Find the longest suffix inside the window. When stops, Left points // at the diverging point in the current sequence. Left--; } bool DuplicationFound = (Left < LeftBoundary); // Don't need to recheck the data before Right LeftBoundary = Right + 1; if (DuplicationFound) { // Duplication found, skip right half of the window. Right += I; } else { // Copy the non-common-suffix part of the adjacent sequence. std::copy(BeginIter + Right + 1, BeginIter + Left + I + 1, BeginIter + End); End += Left + I - Right; // Only slide the window by the size of non-common-suffix Right = Left + I; } } // Don't forget the remaining part that's not scanned. std::copy(BeginIter + Right + 1, Context.end(), BeginIter + End); End += Context.size() - Right - 1; I++; Context.resize(End); MaxDedupSize = std::min(static_cast(End / 2), MaxDedupSize); } } protected: // Lookup or create FunctionSamples for the context FunctionSamples &getFunctionProfileForContext(StringRef ContextId, bool WasLeafInlined = false); // Post processing for profiles before writing out, such as mermining // and trimming cold profiles, running preinliner on profiles. void postProcessProfiles(); void computeSummaryAndThreshold(); void write(std::unique_ptr Writer, StringMap &ProfileMap) override; // Thresholds from profile summary to answer isHotCount/isColdCount queries. uint64_t HotCountThreshold; uint64_t ColdCountThreshold; // String table owning context strings created from profile generation. std::unordered_set ContextStrings; private: // Helper function for updating body sample for a leaf location in // FunctionProfile void updateBodySamplesforFunctionProfile(FunctionSamples &FunctionProfile, const FrameLocation &LeafLoc, uint64_t Count); void populateFunctionBodySamples(FunctionSamples &FunctionProfile, const RangeSample &RangeCounters, ProfiledBinary *Binary); void populateFunctionBoundarySamples(StringRef ContextId, FunctionSamples &FunctionProfile, const BranchSample &BranchCounters, ProfiledBinary *Binary); void populateInferredFunctionSamples(); public: // Deduplicate adjacent repeated context sequences up to a given sequence // length. -1 means no size limit. static int32_t MaxCompressionSize; }; using ProbeCounterMap = std::unordered_map; class PseudoProbeCSProfileGenerator : public CSProfileGenerator { public: PseudoProbeCSProfileGenerator(const BinarySampleCounterMap &Counters) : CSProfileGenerator(Counters) {} void generateProfile() override; private: // Go through each address from range to extract the top frame probe by // looking up in the Address2ProbeMap void extractProbesFromRange(const RangeSample &RangeCounter, ProbeCounterMap &ProbeCounter, ProfiledBinary *Binary); // Fill in function body samples from probes void populateBodySamplesWithProbes(const RangeSample &RangeCounter, SmallVectorImpl &ContextStrStack, ProfiledBinary *Binary); // Fill in boundary samples for a call probe void populateBoundarySamplesWithProbes( const BranchSample &BranchCounter, SmallVectorImpl &ContextStrStack, ProfiledBinary *Binary); // Helper function to get FunctionSamples for the leaf inlined context FunctionSamples & getFunctionProfileForLeafProbe(SmallVectorImpl &ContextStrStack, const PseudoProbeFuncDesc *LeafFuncDesc, bool WasLeafInlined); // Helper function to get FunctionSamples for the leaf probe FunctionSamples & getFunctionProfileForLeafProbe(SmallVectorImpl &ContextStrStack, const PseudoProbe *LeafProbe, ProfiledBinary *Binary); }; } // end namespace sampleprof } // end namespace llvm #endif